Recovery of Recombinant Crimean Congo Hemorrhagic Fever Virus Reveals a Function for Non-structural Glycoproteins Cleavage by Furin
Crimean Congo hemorrhagic fever (CCHF) is a severe viral disease characterized by rapid-onset fever, hemorrhage, and high case fatality rates. CCHF virus (CCHFV), the causative agent of CCHF, is a negative-strand RNA virus of the family Bunyaviridae (genus Nairovirus). No specific treatments or efficacious vaccines exist to combat CCHF. To investigate molecular determinants of nairovirus pathogenesis and biology, we developed a reverse genetics system capable of generating CCHFV variants with genome sequences defined by the plasmids transfected into cells for virus recovery. Our system is the first to demonstrate that a nairovirus can be efficiently recovered from the simple transfection of plasmid DNA, paving the way for specifically editing genomes of CCHFV and other nairoviruses. Using this system, we engineered mutations blocking the cleavage of CCHFV’s non-structural glycoproteins at a motif recognized by the host protease furin. Using this furin-resistant CCHFV variant, we demonstrate that direct cleavage of the viral glycoprotein by furin results in a lag in virion production, revealing a function of these glycoproteins in efficient CCHFV replication. Our experiments highlight the utility of a reverse genetics system for developing viral variants for investigating CCHFV protein function and for rationally designing vaccine strains.
Published in the journal:
Recovery of Recombinant Crimean Congo Hemorrhagic Fever Virus Reveals a Function for Non-structural Glycoproteins Cleavage by Furin. PLoS Pathog 11(5): e32767. doi:10.1371/journal.ppat.1004879
Category:
Research Article
doi:
https://doi.org/10.1371/journal.ppat.1004879
Summary
Crimean Congo hemorrhagic fever (CCHF) is a severe viral disease characterized by rapid-onset fever, hemorrhage, and high case fatality rates. CCHF virus (CCHFV), the causative agent of CCHF, is a negative-strand RNA virus of the family Bunyaviridae (genus Nairovirus). No specific treatments or efficacious vaccines exist to combat CCHF. To investigate molecular determinants of nairovirus pathogenesis and biology, we developed a reverse genetics system capable of generating CCHFV variants with genome sequences defined by the plasmids transfected into cells for virus recovery. Our system is the first to demonstrate that a nairovirus can be efficiently recovered from the simple transfection of plasmid DNA, paving the way for specifically editing genomes of CCHFV and other nairoviruses. Using this system, we engineered mutations blocking the cleavage of CCHFV’s non-structural glycoproteins at a motif recognized by the host protease furin. Using this furin-resistant CCHFV variant, we demonstrate that direct cleavage of the viral glycoprotein by furin results in a lag in virion production, revealing a function of these glycoproteins in efficient CCHFV replication. Our experiments highlight the utility of a reverse genetics system for developing viral variants for investigating CCHFV protein function and for rationally designing vaccine strains.
Introduction
Crimean Congo hemorrhagic fever virus (CCHFV) is a severe human pathogen transmitted through tick bites or contact with infected animals or patients. In ~5–40% of the cases, patients suffer from profound hemorrhage leading to shock and death. CCHFV was first isolated in the Democratic Republic of the Congo in 1956, and later classified into the family Bunyaviridae, genus Nairovirus [1]. The family also includes the genera Orthobunyavirus, Hantavirus, Phlebovirus, and Tospovirus. Today, CCHFV is recognized as endemic in several countries of Africa, Europe, Asia, and the Middle East, where the main vector, hard ticks of the genus Hyalomma, are found [1]. Recent emergence and re-emergence of Crimean Congo hemorrhagic fever (CCHF) in Turkey, southern Russia, Balkans, Democratic Republic of the Congo, Sudan, Uganda, Pakistan, and India have spurred concerns over the spread of this disease to other countries where ticks vectors are present [2,3].
The initial phase of CCHF consists of an acute febrile prodrome indistinguishable from that caused by several other viral infections. However, in less than a week, CCHF often progresses into a life-threating illness characterized by leucopenia, high levels of pro-inflammatory cytokines, coagulopathy, liver necrosis, and hemorrhage [4]. These pathological findings likely reflect a pro-inflammatory immune response mounted against viral infection, and the resulting tissue damage. The high virulence, absence of effective treatments, and documented person-to-person transmission of CCHFV have justified its inclusion on the list of agents requiring biosafety level 4 (BSL-4), the highest level of containment, to perform experimental work [5].
The genome of nairoviruses is distributed on 3 negative-sense RNA segments designated small (S), medium (M), and large (L). The S segment encodes the nucleoprotein (N) that encapsidates the viral genome to form ribonucleoprotein particles (RNPs). The M segment encodes a ~1700 amino acid precursor that is processed into structural glycoproteins (Gn and Gc) that decorate the surface of virions, non-structural M protein (NSm) [6], and secreted non-structural glycoproteins (NSGs) GP85, GP160, and GP38 [7,8]. L segment mRNA is translated into an unusually large (~450 kDa) RNA-dependent RNA polymerase (L-RdRp) that replicates and transcribes viral RNA [9].
Nairovirus glycoprotein biosynthesis is more complex than that of other bunyaviruses in terms of size, functional domains, and the number of mature proteins produced [7,8]. Synthesis of the CCHFV M segment polyprotein is targeted to the endoplasmic reticulum, where the signal peptidase complex rapidly cleaves it into NSm, the membrane bound Gn precursor (PreGn), and the Gc precursor (PreGc) [7]. PreGn and PreGc are further modified by addition of N-linked sugars, and cleaved into Gn and Gc by highly specific host endoproteases in an early compartment of the secretory pathway. PreGn is processed by the site-1 protease (S1P, also known as subtilisin kexin isozyme-1 [SKI-1]), a member of the proprotein convertase (PC) family. PreGc is matured by an unidentified host convertase [10]. S1P activity leads to the selective incorporation of Gn and Gc into nascent virions [11], and to the secretion of NSGs containing 2 domains specific to nairoviruses: a heavily O-glycosylated and variable mucin-like domain (MLD), and a GP38 domain [8]. Three NSGs are observed in the extracellular milieu of CCHFV-infected cells: GP160 and GP85, which contain both MLD and GP38 domains; and GP38, a cleavage product of GP160/GP85 lacking the MLD domain [8]. It is currently unclear what accounts for the differential migration of GP160 and GP85 on SDS-PAGE, as neither tertiary structures nor glycosylation appear to contribute. GP85 probably contains a shorter polypeptide chain while still sharing common epitopes with GP160 in both MLD and GP38 domains [8,12]. The last processing step leading to GP38 secretion occurs at a canonical furin-like PC motif (RSKR↓) in a late compartment of the secretory pathway [8], most likely in the trans-Golgi network (TGN) where furin concentrates [13]. Cleavage of NSGs by furin and/or PCs with related specificity leads to the secretion of GP38.
Recovery of recombinant viruses from cloned complementary DNA allows the design of viruses with precisely defined genomic sequences. This permits researchers to elucidate viral protein function in the context of infection. Viruses with tailored genomes are useful for designing viral variants and live attenuated vaccines harboring engineered mutations and/or gene deletions. This powerful technology has not been available for nairoviruses, a deficiency that has seriously limited our understanding of CCHFV biology and pathogenesis. Here, we describe a method utilizing codon optimization of CCHFV’s L-RdRp to support the recovery of infectious CCHFV entirely from cDNA transfection. Using this system, we investigate the possible role of NSG cleavage in CCHFV life cycle.
Results
Recovery of recombinant CCHFV
We previously reported the reconstitution of transcriptionally active CCHFV RNPs by co-transfecting 2 plasmids producing the L-RdRp and N proteins together with a surrogate RNA minigenome synthesized by bacteriophage T7 RNA polymerase (T7 Pol) [9]. These minigenomes are composed of the viral promoter sequences (3′ and 5′ non-coding regions) of the S, M, or L, and a luciferase gene in place of the viral open reading frame (ORF). The co-transfection of a minigenome together with the L-RdRp and N proteins yielded luciferase activity [9], demonstrating the feasibility of reconstituting CCHFV RNPs. In order to recover infectious CCHFV from cloned cDNA, the complete S, M, and L segments were cloned between a T7 promoter to drive the transcription of CCHFV complementary genomic RNA copies, and a hepatitis D ribozyme to obtain authentic 3′ termini (S1A Fig).
Our first attempts consisted of transfecting 3 plasmids producing complementary (positive sense) copies of the CCHFV S, M, and L segments into cells stably expressing T7 (BSR-T7/5; S1 Fig). We chose to use positive-sense RNA segments over negative-sense, as uncapped T7 transcripts could be translated into enough viral proteins to launch CCHFV replication, as previously demonstrated for other bunyaviruses and arenaviruses [14–16]. In addition, most rescue systems for negative-strand RNA viruses rely on producing positive-sense transcripts to avoid the formation of double-stranded RNA between the negative-sense T7 transcripts and positive-sense support plasmids that are often required [17]. Transfection of only pT7-S, pT7-M, and pT7-L, failed to rescue CCHFV, possibly because the CCHFV L segment is extremely long compared to the L of arenaviruses and bunyaviruses and could make reconstituting RNPs less efficient.
To improve reconstitution of RNPs containing full-length L, we supplemented the transfection reactions with expression vectors pC-L and pC-N (S1B Fig, pC-L + pC-N), producing the L-RdRp and N from a strong RNA polymerase II promoter that has been previously used to successfully replicate minigenomes of all CCHFV segments [9]. Despite multiple attempts and protocol modifications, no CCHFV was recovered using this set of plasmids. Western blot analysis of the L-protein from pC-L transfections revealed that only a small amount of the full-length L-RdRp had been produced [9]. We hypothesized that low abundance of full-length L-RdRp might be preventing the replication of full-length CCHFV RNA transcripts. Since bunyavirus transcription naturally occurs in the cytoplasm, we suspected that the L transcripts produced in the nucleus might yield truncated L-RdRp products due to aberrant splicing and/or premature termination of transcription by PolII. In an attempt to increase the amount of ~450 kDa L-RdRp product and improve viral RNA synthesis, we produced a synthetic V5-tagged L-RdRp codon optimized for expression in human cells (pC-L opti). The algorithms used to generate this L sequence maximize the usage of preferred human codons and remove potential cryptic splicing sites and secondary structures [18] that might interfere with transcription and translation of full-length L-RdRp. We first tested the effects of L gene codon optimization on L-RdRp activity using a luciferase minigenome system. Codon optimization led to ~7-fold increase in L-RdRp activity and more robust production of the full-length L-protein, confirming that codon optimization greatly improves L-RdRp activity and expression (Fig 1A and 1B). Therefore, we used pC-L opti instead of wild-type (WT) pC-L in subsequent attempts to rescue CCHFV.
Since CCHFV does not cause obvious cytopathic effect in permissive BSR-T7/5 cells, a PreGn mAb (7F5) was used to rapidly detect possible rescue of CCHFV directly in the transfected cells. This was possible because foci of > 10 cells with discernable Golgi-like perinuclear staining could only be observed when CCHFV was present as opposed to transfection of pT7-S,-M, and-L alone. Four days after transfection of BSR-T7/5 cells with pC-L opti, immunoreactive foci of infection were detected, suggesting the recovery of CCHFV from cDNA (Fig 1C). Supernatants from transfected BSR-T7/5 cells were then transferred to highly susceptible SW13 cells, which show apoptosis-induced cytopathic effect upon CCHFV infection [20]. Three days later, cytopathic effect were evident in these cells, and CCHFV antigens were detected throughout the cell monolayer. Growth kinetics of recombinant CCHFV in RIG-I signaling deficient (BSR-T7/5) [21] and competent (A549) cells matched those of the parental virus isolate (Fig 2). These data confirmed that infectious nairoviruses can be obtained entirely from cloned DNA in our system.
Rescue optimization
After confirming CCHFV rescue, we optimized the system by varying the ratios of plasmids used in order to maximize rescue efficiency. We first tested the effect of adding exogenous T7 Pol. Without expressing plasmid-derived T7, we rescued CCHFV in 2 out 3 experiments (Fig 3A). In comparison, adding pC-T7 plasmid to the plasmid mix yielded rescue in 6/6 experiments and similar CCHFV titers over the 5-day experimental period (Fig 3B, ratio 2:1). We concluded that additional T7 is not required but overall not detrimental to rescue efficiency. Stable expression of T7 in BSR-T7/5 can vary with passaging and requires a strict antibiotic selection regimen [14], so being able to use exogenous T7 Pol can be useful.
Since adding pC-T7 was not detrimental to rescue efficiency, we continued to add pC-T7 in subsequent rescue experiments to mitigate any potential variation in the stable expression of T7 Pol from BSR-T7/5 cells. The ability to add T7 also allowed us to determine if CCHFV could be efficiently rescued in cell lines that do not stably express T7. The human hepatocyte cell line Huh7 was transfected with pC-T7, pC-N, pC-L opti and pT7-S,-M, and-L; virus was detected, and viral titers were measured by tissue culture infective dose (TCID50) determination 2–5 days post transfection. CCHFV was rescued from Huh7 cells in 3/3 experiments, and infectious virus titers peaked at 4 days post transfection (S2 Fig) with no significant differences from levels seen in BSR-T7/5 cells when using a 2:1 pC-N:pC-L opti plasmids ratio (Fig 3B, ratio 2:1).
We next determined if increasing support plasmid ratios affected rescue efficiency. Recombinant CCHFV was detected as early as 2 days post transfection when pC-N and pC-L opti were used in a 2:1 ratio, and ~10-fold higher viral titers were obtained 3 days post transfection than when using a 19:1 ratio of these plasmids (Fig 3B). However, rescue efficiency remained 100% with both ratios tested, and viral titers peaked 4–5 days post transfection independently of the ratios of support plasmids used.
Finally, we varied the ratios of plasmids used to express the full-length complement RNA of the 3 CCHFV segments (pT7-S, pT7-M, and pT7-L) while keeping the 2:1 ratio of support plasmids (Fig 4). At 4 days post infection, the same viral titers of ~1 × 105 TCID50/mL were obtained at all ratios tested, except for the 2.5:1:1 (S:M:L) ratio, which did not yield measurable CCHFV titers.
Role of furin in CCHFV infection
Within the family Bunyaviridae, only nairoviruses produce NSGs or viral glycoprotein precursors subjected to PC cleavage [8,10,22]. In most cases, the cleavage of structural viral glycoproteins promotes viral replication by allowing the entry of the virus into host cells. Interestingly, Ebola virus, a filovirus that causes highly fatal hemorrhagic fever, synthesizes NSGs and a structural glycoprotein precursor containing MLD and furin-like PC cleavage motifs (RTRR↓) [23,24]. Unlike most viral glycoproteins cleaved by furin-like PCs, Ebola virus glycoprotein cleavage appeared to have little or no effect on viral replication, as infectious virus was still produced in mutants with blocked processing of the glycoprotein precursor [25,26]. We therefore endeavored to determine whether cleavage of CCHFV glycoprotein at the RSKR247 site was critical for CCHFV propagation (Fig 5).
The importance of furin-like PCs in the propagation of CCHFV and control Rift Valley fever virus (RVFV) was evaluated by infecting cells deficient in furin. The parental Chinese hamster ovary (CHO)-derived cell lines (Par6), furin-deficient (FD11) [27], and furin-reconstituted FD11 (FD11-Fur) were infected with CCHFV or RVFV at multiplicity of infection (MOI) of 1 or 0.1, respectively, and percentages of infected cells were determined 24 and 48 h post infection (Fig 6A). After 24 h, 37% of Par6 cells and 36% of FD11-Fur cells were infected with CCHFV, compared to 4% of FD11 cells not expressing furin. After 48 h, Par6 and FD11-furin cell monolayers were totally infected, while only 18% of the FD11 cells where infected (Fig 6B). In comparison, the replication of RVFV, which does not contain known furin-like PC cleavage motifs in its glycoprotein sequence, was similar in all cell lines, supporting the hypothesis that glycoprotein cleavage at a putative RSKR motif enhances CCHFV replication. Alternatively, furin might indirectly regulate CCHFV spread by processing host proteins implicated in its life cycle.
Generating CCHFV producing endoproteolysis-resistant NSGs
To clarify whether furin or general NSG cleavage is required for CCHFV replication, we first sought to recover a CCHFV with a glycoprotein resistant to furin-like PC endoproteolysis. The substrates of furin-like PCs are normally cleaved at the general (R/K)-2nX-R↓ motif, where n = 0–3 amino acids [28]. The canonical motif (RSKR↓) is located at the junction of the MLD and GP38 domains of CCHFV (Fig 5A). To block processing at this site, we mutated the ORF encoded by the pT7-M plasmid, so that Arg residues at positions 1 and 4 were changed to Ala (RSKR to ASKA). Given the specificity of furin-like PCs, these mutations should block the conversion and production of GP38. The pT7-M-ASKA plasmid was transfected together with plasmids needed to produce recombinant CCHFV, and a viable recombinant virus (CCHFV-ASKA) was recovered. Like WT CCHFV, the rescued CCHFV-ASKA mutant produced extensive cytopathic effect in SW13 cells. In cells infected with CCHFV-ASKA, PreGn colocalized with a Golgi marker, similarly to WT CCHFV (S3 Fig). Sequencing the M segment from this mutant virus confirmed mutations only at the cleavage site mutations.
To confirm that the ASKA mutation blocked NSG processing, viral proteins extracted from lysates of infected cells were analyzed using antibodies directed against PreGn/Gn, PreGc/Gc, and N. Densitometry analysis of the precursor and mature Gn and Gc indicated no change in Gc:PreGc ratios, while the Gn:PreGn ratio was slightly reduced in ASKA mutants (Fig 7A). The anti-GP38 antibody also detected PreGn but GP160/85 and GP38 did not accumulate in cells to detectable levels (S4 Fig).
To detect the secreted NSGs, supernatants of infected cells were immunoprecipitated using a mAb directed against the GP38 domain. Polyacrylamide gel electrophoresis revealed GP160/GP85 and GP38 presence upon infection with WT CCHFV (Fig 7B). In comparison, CCHFV-ASKA infection produced abundant GP160/GP85, but only trace amounts of GP38. Thus, mutating RSKR to ASKA selectively impaired maturation of the glycoprotein precursor to GP38, and slightly reduced PreGn conversion to Gn.
Direct role of furin cleavage at RSKR motif in virion production
Since CCHFV-ASKA mutations effectively blocked the production of GP38, we addressed the role of GP38 in the production of infectious CCHFV. FD11 and FD11-Fur cells were infected with CCHFV-WT or CCHFV-ASKA, and viral loads and associated viral RNA levels were measured for 5 days after infection by, respectively, TCID50 determination and qRT-PCR (Fig 8). Furin-reconstituted cells (FD11-Fur) infected with CCHFV-WT yielded ~10-fold more infectious virus and viral RNA than the same cells infected with CCHFV-ASKA, but only 1 day post infection. In comparison, no differences were noted in furin-deficient cells (FD11; Fig 8).
Discussion
Despite increasing numbers of reported CCHF cases and disease severity, the life cycle of CCHFV remains poorly defined. Here, we present an efficient method to recover recombinant infectious CCHFV entirely from cDNA. This technical accomplishment should facilitate investigations of CCHFV replication cycle, pathogenesis, and transmission. Furthermore, we demonstrate the utility of this reverse genetics virus rescue system by generating a specifically designed CCHFV mutant, and provide direct evidence that cleavage at RSKR by furin-like PCs enhances the virion production of this severe pathogen.
Rescue system development and optimization
Prior to codon optimization of the L-gene in the support plasmid, all attempts to generate CCHFV failed. Notably, the same plasmid vector stocks expressing complementary copies of the 3 viral segments (pT7-S, pT7-M, and pT7-L) were used in all of our unsuccessful and successful attempts, suggesting that inefficient synthesis of full-length L-RdRp might explain our initial inability to rescue recombinant CCHFV (Fig 1). The increase in L-RdRp expression upon introducing the optimized L construct was seen in both L-RdRp yield and activity (Fig 1A). The recoded, optimized L (pC-L opti) efficiently launched viral replication and allowed us to obtain infectious CCHFV with a tailored genome. CCHFV infection persists in ticks and its replication cycle is exclusively cytoplasmic. It is plausible that evolutionary pressure exerted by the tick host cells and adaption for cytoplasmic transcription could explain the difficulty in producing large amounts of L-RdRp from the nucleus of mammalian cells using CCHFV’s natural codons (Fig 1B). Our failure to recover CCHFV when using WT pC-L in previous attempts suggested that in silico recoding may be important for systematically recovering recombinant CCHFV.
Synthetic genes can also be introduced into the genome of viruses using reverse genetics. Introduction of rare codon pairs in poliovirus and influenza virus genes leads to reduced viral protein production, strong attenuation in vivo, and prototype vaccines that can confer complete protection against homologous virus challenges [29,30]. As efficacious CCHF vaccines are critically needed, a similar codon deoptimization approach could now be attempted in order to obtain a live, attenuated CCHFV vaccine candidate.
Robust recue systems are critical for obtaining mutant viruses, especially those with severe growth defects. Herein, we describe optimization of the rescue protocol that yielded recombinant CCHFV in virtually every transfection attempted. Although not required for rescue in cells stably expressing T7 Pol, exogenously added pC-T7 did not negatively impact rescue efficiency in BSR-T7/5 cells. Adding pC-T7 further allowed us to rescue CCHFV in Huh7 cells, a human hepatocyte cell line not stably expressing T7 Pol. This demonstrates that our rescue system is robust and could be easily transposed to a cell line of human origin without cell specific optimization. The option of using other cell lines might be particularly important in the eventuality of mutations preventing CCHFV recovery in BSR-T7/5 due to low or absent expression of cell- or species-specific host factors.
Optimal rescue conditions should yield the highest viral titers at early times post-transfection. By varying support plasmid ratios (pC-N:pC-L opti), we observed that lower ratios increased CCHFV yield by ~10-fold 3 days post transfection, showing that reducing the expression of codon-optimized L-RdRp is detrimental to virus rescue. Nevertheless, even lower amounts of codon-optimized L-RdRp eventually yielded high titers of CCHFV at later time points. In contrast, increasing the ratio of pT7-S to pT7-M and-L dramatically reduced virus rescue efficiency, as noted by the absence of detectable CCHFV at 4 days post transfection when using an S:M:L ratio of 2.5:1:1 (Fig 4). This finding suggests that overrepresentation of the plasmid producing the S segment complementary genome should be avoided. The smaller size of pT7-S could explain these phenomena, as T7 Pol. may preferentially synthesize smaller segments more efficiently, thereby requiring less pT7-S input than pT7-M and pT7-L.
The role of furin-like cleavage in efficient production of CCHFV
Limited endoproteolysis is a common mechanism exploited by viruses to modulate the activity of their glycoprotein precursors, and CCHFV uses PCs with non-overlapping specificity to generate GP38 and Gn. Previous biochemical analyses of the M-polyprotein have revealed the role of host proteases in the complex biosynthesis of at least 8 different proteins from a single protein [6,8]. Our past efforts highlighted the critical function of S1P in assembling infectious CCHFV [11], but the contribution of furin-like PCs in viral replication remained unexplored. Using the CCHFV reverse genetics system, we addressed the function of this cleavage on CCHFV replication without the need to rely on furin-like PC inhibitors. This is particularly important, as inhibition of furin-like PCs could also modulate the activity of other cellular receptors, ligands, growth factors, and enzymes that could indirectly affect CCHFV replication independently of glycoprotein processing. The conservation of basic amino acids in the RSKR motif among all CCHFV strains from diverse endemic areas (S5 Fig) suggests selective pressure for furin-like PC cleavage at this particular site.
Structural analysis of RVFV Gc revealed that the overall architecture of bunyavirus Gc resembles that of class II fusion proteins of West Nile virus and Sindbis virus, whose companion proteins are cleaved by furin-like PCs. However, neither RVFV Gc nor the companion protein Gn is obtained by PC activity. Therefore, it became critical to determine whether cleavage of CCHFV glycoprotein, both by furin-like PCs at the putative RSKR motif and by SKI-I/S1P at the RRLL motif, is necessary for efficient spread and production of CCHFV, or whether furin-like PC cleavage simply fulfills accessory functions dispensable for viral replication. To address the function of CCHFV glycoprotein cleavage at the RSKR motif in virus propagation, we obtained a recombinant CCHFV variant, CCHFV-ASKA, which produced glycoprotein precursors resistant to furin-like PC activity. The simple recovery of ASKA mutant virus demonstrated that furin-like PC cleavage is not an essential step in CCHFV replication in cell culture, and enabled us to study the function of cleavage at this site without being obligated to manipulate cellular functions with inhibitors, siRNA, or gene overexpression.
Consistent with the preference of furin-like PCs for Arg residues at P1 and P4, the CCHFV-ASKA glycoprotein profile confirmed that mutating P1 and P4 selectively blocked glycoprotein processing to GP38. To a less significant extend, mutations reduced the Gn:PreGn ratio, but the Gc:PreGc ratio was unaffected. The fact that mature Gn was still produced is compatible with the rapid production of PreGn by S1P early in the secretory pathway (endoplasmic reticulum/early Golgi); furin, on the other hand, is localized in the trans-Golgi network, and the cleavage yielding GP38. Consequently, we propose that S1P PreGn cleavage into Gn and MLD-containing NSGs (GP160/85) precedes furin-like PC cleavage, and that the distinct localization of S1P and furin might dictate the proper sequence of cleavage events that yields the complete set of structural and non-structural glycoproteins. However, our data also suggest that furin processing could indirectly increase PreGn to Gn conversion performed by S1P. It remains to be shown if furin does indeed cleave a pool of PreGn prior to S1P and if prior cleavage at RSKR site would enhance Gn production.
The relative ease of propagating the CCHFV-ASKA mutant appears in stark contrast with the total loss of CCHFV infectivity when S1P is not expressed [11]. Further experiments were performed to address the function of furin-like PCs in the replication of CCHFV, using RVFV as a PC-independent control. Although our data do not exclude the potential role of other furin substrates in CCHFV’s life cycle, our findings certainly stress a specific role of furin cleavage at the RSKR site. This conclusion is supported by higher WT CCHFV production than CCHFV-ASKA production in cells expressing furin (Fig 8). If furin cleavage at RSKR did not contribute to CCHFV’s replication, then this difference would also be expected in furin-deficient cells. Therefore, we conclude that cleavage at the putative furin-like PC motif is not essential for CCHFV production, but furin cleavage at RSKR enhances virion production.
Despite evolutionary conservation of the RSKR motif, our in vitro replication experiments confirm that this cleavage event is dispensable for the production or cell-to-cell spread of CCHFV. The biological relevance of CCHFV NSGs remains unknown, and no specific ligands have been determined for any of them. Intriguingly, the decrease in CCHFV-ASKA production was transient, and CCHFV-ASKA levels matched those of WT-CCHFV 2 days and later post infection, perhaps because furin cleavage affects virion production early during the infection when the levels of glycoproteins are lower. Studies focused on NSG function in conjunction with detailed biosynthesis of the various M-polyprotein glycoprotein products are warranted to precise the function of furin cleavage of CCHFV glycoproteins. Even though modest, reduction in PreGn to Gn certainly merits further consideration given the essential role of S1P in Gn biosynthesis [10] and CCHFV infectivity [11]. But how could furin cleavage at RSKR site increase S1P cleavage at RRLL? One possibility could be trimming of PreGn from its MLD by furin. In this scenario, PreGn would escape S1P cleavage and travel to the trans-Golgi network, where furin would trim off its MLD (Fig 5); this, in turn, would facilitate the kinetics of Gn production and subsequent virion production. CCHFV assembly occurs at the Golgi or trans-Golgi network, and after assembly, the intracellular vesicles containing viruses are transported toward the cell surface, where they are released by exocytosis. CCHFV GP38 is secreted by exocytosis, but is not tightly associated with extracellular CCHFV particles [8]. Since we observe a reduction in CCHFV-ASKA production in the extracellular milieu and GP38, we speculate that GP38 could be involved in the efficient sorting and/or release of mature CCHFV particles. We propose that future studies should consider the possible impact of furin cleavage of the MLD on Gn formation and investigate the role of GP38 on CCHFV production.
Recently, an experimental in vivo model of CCHFV transmission from ticks to vertebrates [31], and a model of CCHF pathogenesis [32] in mice, were reported. These in vivo systems, combined with the power of reverse genetics, offer unique opportunities to characterize CCHFV protein functions in various aspects of virus pathogenesis and biology. Our study lays important groundwork to further define how NSGs and their cleavage by furin-like PCs affect CCHFV biology and pathogenesis in the mouse model, and the persistence and transmission of CCHFV in the tick vector. The function of NSGs is particularly intriguing because filoviruses from the genus Ebolavirus also secrete glycoproteins that contain an MLD and are cleaved by furin-like PCs. Therefore, it is critical to better characterize the function of these secreted glycoproteins that might share a common mechanism to cause severe hemorrhage and death in humans.
In conclusion, this work highlights the ability of experimentally producing CCHFV variants entirely from cDNA. Using CCHFV reverse genetics, we efficiently recovered WT virus and a virus variant encoding a glycoprotein precursor resistant to furin-like PC cleavage. This mutant CCHFV was used to specifically examine the role of furin-like PC cleavage on virus propagation. In the future, this reverse genetics systems could be used to experimentally identify genetic determinants of virulence, critical functions of viral proteins, non-coding regions of the viral genome, and in the rational design of live attenuated vaccines.
Materials and Methods
Cells and viruses
SW13 cells, a generous gift from P. Leyssen (Rega Instituut KU Leuven, Belgium), were cultured in DMEM supplemented with 10% FBS and 1 mM sodium pyruvate. BSR-T7/5 were a generous gift from K.K. Conzelmann (Ludwig-Maximilians-Universität, Munich, Germany), and maintained as described before [14]. Vero-E6 and A549 (both from American Type Cell Collection) cells were maintained in DMEM + 10% FBS. All cell culture media were supplemented with 100 units/mL of penicillin and streptomycin. Parental CHO-derived cells (Par6), furin-deficient Par6 cells (FD11), and FD11 stably expressing furin (FD11-Fur) were kindly provided by Stephen Leppla (National Institute of Health, Bethesda, MD, USA); these cell lines were maintained in MEM-alpha medium with 10% FBS. CCHFV strain IbAr10200 (former Yale Arbovirus Research Unit, CT, USA) was isolated in Nigeria in 1965 from ticks, and has a passaging history in suckling mice and Vero-E6 cells.
Plasmids
CCHFV RNA was extracted with Tripure reagent (Roche Diagnostics Corp, Indianapolis, IN, USA) using manufacturer’s protocol. Full-length cDNA from the S, M, and L segments was obtained by reverse transcription of CCHFV RNA at 50°C (Thermoscript RT, Invitrogen, Grand Island, NY, USA) using a DNA primer complementary to the 3′ end of the viral genomic RNAs. Complete cDNA were sequence-amplified by PCR using high fidelity Phusion enzyme (New England Biolabs, Ipswich, MA, USA) and cloned into the pT7 vector. The pT7 vector was previously described as V (0.0)/B [14], and contains a BsmB1 cloning site located between a T7 promoter and a hepatitis D ribozyme T7 polymerase terminator motif [14]. The S, M, and L cDNAs were cloned into the BsmB1-digested pT7 vector in viral complementary orientation relative to the T7 promoter (S1 Fig). Sequences of all plasmids used to rescue CCHFV are available in GenBank. Primary T7 transcripts derived from pT7-S (KJ648914), pT7-M (KJ648915), and pT7-L (KJ648913) contain an artificial G at the 5′ ends, but this nucleotide is rapidly lost upon replication [9]. pC-N (KJ648912), pC-L (KJ648911), and T7-M-Renilla constructs were described previously [9,19]. pT7-M-ASKA (KJ648916) was obtained by PCR mutagenesis of pT7-M using QuickChange Lightning Site Directed Mutagenesis Kit (Agilent Technologies, Santa Clara, CA, USA) per manufacturer’s instructions. pC-L opti (KJ648910) was obtained by optimizing the codons of CCHFV IbAr10200 L ORF for maximal expression in human cells [18] (GeneArt, Ratisbonne, Germany). Both pC-L and pC-L opti were tagged with an N-terminal V5 epitope. pC-T7 [33] was obtained by cloning human codon-optimized bacteriophage T7 RNA Pol (Genscript, Piscataway, NJ, USA) into pCAGGS.
Minigenome and virus rescue
The T7-M-Renilla minigenome has been previously described [19]. This minigenome is based on our previous Gaussia luciferase version that necessitated transfection of in vitro minigenome transcripts to minimize background activity [9]. In combination with codon optimization of the L-polymerase, changing Gaussia to Renilla luciferase reporter yielded negligible background levels, thereby eliminating the requirement of producing in vitro minigenome transcripts. All attempts to recover CCHFV were performed in BSL-4 facilities at the Centers for Disease Control and Prevention (Atlanta, GA, USA). Six-well plates were seeded with 3.5 × 105 BSR-T7/5 cells/well 1 day prior to transfection in 3 mL of DMEM supplemented with 5% FBS. 16–24 h later, cells were transfected with the indicated amounts of pT7-S, pT7-M, pT7-L, pC-L opti, pC-N, and optionally with pC-T7, combined with 2.5 μL of Mirus LT1 transfection reagent (Mirus Bio, Madison, WI, USA) per μg of DNA in 250 μL of OPTI-MEM (Life Technologies, Grand Island, NY, USA). For CCHFV-ASKA rescue, pT7-M was substituted with pT7-M-ASKA. 16–24 h post transfection, 5 mL of DMEM with 2% FBS was added to each transfected well. Cell supernatants were harvested 4 days post infection, and 2 mL of supernatant were passaged to a 75 cm2 confluent flask of SW13 cells grown in DMEM with 10% FBS and 1 mM sodium pyruvate. All viruses were titrated using a standard TCID50 protocol in SW13 cells.
Immunofluorescence
Cells were fixed with 10% formalin buffered solution. BSR-T7/5 cells were incubated with a CCHFV-specific glycoprotein antibody (7F5, USAMRIID, Fort Detrick, MD, USA) or with hyperimmune mouse ascetic fluid (HMAF) for SW13 cells, followed by incubation with goat anti-mouse Alexa 488-conjugated antibody (Life Technologies). To determine subcellular localization of CCHFV glycoprotein, Vero-E6 cells were infected with CCHFV-WT or CCHFV-ASKA, and stained with 7F5 mAb and rabbit anti-giantin pAb (Covance, Princeton, NJ, USA), followed by incubation with DAPI to stain nuclei, goat anti-mouse Alexa 488-conjugated secondary antibody, and goat anti-rabbit Alexa 546-conjugated secondary antibody. Images were captured with a TCS SP5 confocal microscope (Leica Microsystems, Buffalo Grove, IL, USA).
Western blotting and metabolic labeling
Western blotting and metabolic labeling were performed as previously described [11,12]. Briefly, Gn, Gc and glycoprotein precursors were detected with rabbit anti-PreGn/Gn (kindly provided by A. Mirazimi, Folkhälsomyndigheten, Sweden) and anti-PreGc/Gc mAb 11E7 (USAMRIID), while N was detected with CCHFV HMAF. For metabolic labeling, SW13 cells were infected with CCHFV at MOI = 0.1 for 6 h. Cells were pulsed overnight with 100 μCi/mL of S35-labeled Met and Cys in normal DMEM supplemented with 1% of low-IgG FBS (Life Technologies). Cell supernatants were cleared of contaminating bovine IgG using protein A/G magnetic beads (Thermo Scientific, Grand Island, NY, USA) before immunoprecipitating secreted GP38-containing glycoproteins with 8C11 mAb, kindly provided by A. Garrison and C. Schmaljohn (USAMRIID). Immunoprecipitated proteins were separated on Tris-acetate NuPAGE 4–8% gradient gels, and labeled proteins were revealed by autoradiography.
Analysis of CCHFV- and RVFV-infected cell cultures
CHO-derived cell lines Par6, FD11, and FD11-Fur, seeded in MEM-alpha medium with 5% FBS, were infected with recombinant CCHFV WT or RVFV-ΔNSs:GFP-ΔNSm [34], and fixed in 10% formalin buffered solution. CCHFV-infected cultures were incubated with CCHFV HMAF and goat anti-mouse Alexa 488-conjugated antibody. Nuclei and cells were respectively counterstained with Hoechst 33342 and HCS CellMask Red stain (Life Technologies). Images were acquired with a 20× objective on an Operetta High Content Imaging system (PerkinElmer Inc, Waltham, MA, USA). To detect RVFV-infected cells, EGFP was measured.
Quantitative RT-PCR
RNA was isolated from cell supernatants using Magmax technology (Life Technologies) and subjected to one-step qRT-PCR using SuperScript III Platinum One-Step qRT-PCR Kit (Life Technologies). CCHFV S segment amplification was performed on an Applied Biosystems 7500 Real-Time PCR System using sense (5′ATGAACAGGTGGTTTGAAGAGTT 3′) and antisense (5′TGGCACTGGCCATCTGA 3′) primers, and TaqMan probe (5′[6-carboxy-fluorescein (FAM)] TGTCCAAATTGGGAACACTCTCGCA [BlackBerry Quencher (BBQ)] 3′) (TIB Molbiol, Adelphia, NJ, USA).
Supporting Information
Zdroje
1. Ergonul O (2012) Crimean-Congo hemorrhagic fever virus: new outbreaks, new discoveries. Current Opinion in Virology 2: 215–220. doi: 10.1016/j.coviro.2012.03.001 22482717
2. Estrada-Peña A, Palomar AM, Santibáñez P, Sánchez N, Habela MA, et al. (2012) Crimean-congo hemorrhagic Fever virus in ticks, southwestern europe, 2010. Emerg Infect Dis 18: 179–180. doi: 10.3201/eid1801.111040 22261502
3. Maltezou HC, Andonova L, Andraghetti R, Bouloy M, Ergonul O, et al. (2010) Crimean-Congo hemorrhagic fever in Europe: current situation calls for preparedness. Euro Surveill 15: 19504. 20403306
4. Ergonul O (2006) Crimean-Congo haemorrhagic fever. Lancet Infect Dis 6: 203–214. doi: 10.1016/S1473-3099(06)70435-2 16554245
5. Rotz LD, Khan AS, Lillibridge SR, Ostroff SM, Hughes JM (2002) Public health assessment of potential biological terrorism agents. Emerg Infect Dis 8: 225–230. 11897082
6. Altamura LA, Bertolotti-Ciarlet A, Teigler J, Paragas J, Schmaljohn CS, et al. (2007) Identification of a novel C-terminal cleavage of Crimean-Congo hemorrhagic fever virus PreGN that leads to generation of an NSM protein. J Virol 81: 6632–6642. doi: 10.1128/JVI.02730-06 17409136
7. Sanchez AJ, Vincent MJ, Nichol ST (2002) Characterization of the glycoproteins of Crimean-Congo hemorrhagic fever virus. J Virol 76: 7263–7275. 12072526
8. Sanchez AJ, Vincent MJ, Erickson BR, Nichol ST (2006) Crimean-congo hemorrhagic fever virus glycoprotein precursor is cleaved by Furin-like and SKI-1 proteases to generate a novel 38-kilodalton glycoprotein. J Virol 80: 514–525. doi: 10.1128/JVI.80.1.514-525.2006 16352575
9. Bergeron E, Albariño CG, Khristova ML, Nichol ST (2010) Crimean-Congo hemorrhagic fever virus-encoded ovarian tumor protease activity is dispensable for virus RNA polymerase function. J Virol 84: 216–226. doi: 10.1128/JVI.01859-09 19864393
10. Vincent M, Sanchez A, Erickson B, Basak A, Chretien M, et al. (2003) Crimean-Congo hemorrhagic fever virus glycoprotein proteolytic processing by subtilase SKI-1. J Virol 77: 8640. 12885882
11. Bergeron E, Vincent MJ, Nichol ST (2007) Crimean-Congo hemorrhagic fever virus glycoprotein processing by the endoprotease SKI-1/S1P is critical for virus infectivity. J Virol 81: 13271–13276. doi: 10.1128/JVI.01647-07 17898072
12. Sanchez A, Yang ZY, Xu L, Nabel GJ, Crews T, et al. (1998) Biochemical analysis of the secreted and virion glycoproteins of Ebola virus. J Virol 72: 6442–6447. 9658086
13. Mallet WG, Maxfield FR (1999) Chimeric forms of furin and TGN38 are transported with the plasma membrane in the trans-Golgi network via distinct endosomal pathways. J Cell Biol 146: 345–359. 10465644
14. Albariño CG, Bergeron E, Erickson BR, Khristova ML, Rollin PE, et al. (2009) Efficient reverse genetics generation of infectious junin viruses differing in glycoprotein processing. J Virol 83: 5606–5614. doi: 10.1128/JVI.00276-09 19321606
15. Lowen AC, Noonan C, McLees A, Elliott RM (2004) Efficient bunyavirus rescue from cloned cDNA. Virology 330: 493–500. doi: 10.1016/j.virol.2004.10.009 15567443
16. Bergeron E, Chakrabarti AK, Bird BH, Dodd KA, McMullan LK, et al. (2012) Reverse genetics recovery of Lujo virus and role of virus RNA secondary structures in efficient virus growth. J Virol. doi: 10.1128/JVI.01144-12
17. Whelan SP, Ball LA, Barr JN, Wertz GT (1995) Efficient recovery of infectious vesicular stomatitis virus entirely from cDNA clones. Proc Natl Acad Sci USA 92: 8388–8392. 7667300
18. Raab D, Graf M, Notka F, Schödl T, Wagner R (2010) The GeneOptimizer Algorithm: using a sliding window approach to cope with the vast sequence space in multiparameter DNA sequence optimization. Syst Synth Biol 4: 215–225. doi: 10.1007/s11693-010-9062-3 21189842
19. Carter SD, Surtees R, Walter CT, Ariza A, Bergeron E, et al. (2012) Structure, Function, and Evolution of the Crimean-Congo Hemorrhagic Fever Virus Nucleocapsid Protein. J Virol 86: 10914–10923. doi: 10.1128/JVI.01555-12 22875964
20. Karlberg H, Tan Y-J, Mirazimi A (2011) Induction of caspase activation and cleavage of the viral nucleocapsid protein in different cell types during Crimean-Congo hemorrhagic fever virus infection. J Biol Chem 286: 3227–3234. doi: 10.1074/jbc.M110.149369 21123175
21. Habjan M, Penski N, Spiegel M, Weber F (2008) T7 RNA polymerase-dependent and-independent systems for cDNA-based rescue of Rift Valley fever virus. J Gen Virol 89: 2157–2166. doi: 10.1099/vir.0.2008/002097-0 18753225
22. Plyusnin A, Elliott RM (2011) Bunyaviridae. Horizon Scientific Press. 1 pp.
23. Volchkova VA, Klenk HD, Volchkov VE (1999) Delta-peptide is the carboxy-terminal cleavage fragment of the nonstructural small glycoprotein sGP of Ebola virus. Virology 265: 164–171. doi: 10.1006/viro.1999.0034 10603327
24. Volchkov VE, Feldmann H, Volchkova VA, Klenk HD (1998) Processing of the Ebola virus glycoprotein by the proprotein convertase furin. Proc Natl Acad Sci USA 95: 5762–5767. 9576958
25. Neumann G, Geisbert TW, Ebihara H, Geisbert JB, Daddario-DiCaprio KM, et al. (2007) Proteolytic processing of the Ebola virus glycoprotein is not critical for Ebola virus replication in nonhuman primates. J Virol 81: 2995–2998. doi: 10.1128/JVI.02486-06 17229700
26. Neumann G, Feldmann H, Watanabe S, Lukashevich I, Kawaoka Y (2002) Reverse genetics demonstrates that proteolytic processing of the Ebola virus glycoprotein is not essential for replication in cell culture. J Virol 76: 406–410. 11739705
27. Gordon VM, Klimpel KR, Arora N, Henderson MA, Leppla SH (1995) Proteolytic activation of bacterial toxins by eukaryotic cells is performed by furin and by additional cellular proteases. Infect Immun 63: 82–87. 7806387
28. Seidah NG, Sadr MS, Chretien M, Mbikay M (2013) The multifaceted proprotein convertases: their unique, redundant, complementary, and opposite functions. Journal of Biological Chemistry 288: 21473–21481. doi: 10.1074/jbc.R113.481549 23775089
29. Yang C, Skiena S, Futcher B, Mueller S, Wimmer E (2013) Deliberate reduction of hemagglutinin and neuraminidase expression of influenza virus leads to an ultraprotective live vaccine in mice. Proc Natl Acad Sci USA 110: 9481–9486. doi: 10.1073/pnas.1307473110 23690603
30. Mueller S, Coleman JR, Papamichail D, Ward CB, Nimnual A, et al. (2010) Live attenuated influenza virus vaccines by computer-aided rational design. Nat Biotechnol 28: 723–726. doi: 10.1038/nbt.1636 20543832
31. Gargili A, Thangamani S, Bente D (2013) Influence of laboratory animal hosts on the life cycle of Hyalomma marginatum and implications for an in vivo transmission model for Crimean-Congo hemorrhagic fever virus. Front Cell Infect Microbiol 3: 39. doi: 10.3389/fcimb.2013.00039 23971007
32. Bente D, Alimonti J, Shieh W, Camus G, Stroher U, et al. (2010) Pathogenesis and immune response of Crimean-Congo hemorrhagic fever virus in a STAT-1 knockout mouse model. J Virol 84: 11089. doi: 10.1128/JVI.01383-10 20739514
33. Albariño CG, Uebelhoer LS, Vincent JP, Khristova ML, Chakrabarti AK, et al. (2013) Development of a reverse genetics system to generate recombinant Marburg virus derived from a bat isolate. Virology 446: 230–237. doi: 10.1016/j.virol.2013.07.038 24074586
34. Bird BH, Albariño CG, Hartman AL, Erickson BR, Ksiazek TG, et al. (2008) Rift valley fever virus lacking the NSs and NSm genes is highly attenuated, confers protective immunity from virulent virus challenge, and allows for differential identification of infected and vaccinated animals. J Virol 82: 2681–2691. doi: 10.1128/JVI.02501-07 18199647
Štítky
Hygiena a epidemiológia Infekčné lekárstvo LaboratóriumČlánok vyšiel v časopise
PLOS Pathogens
2015 Číslo 5
- Parazitičtí červi v terapii Crohnovy choroby a dalších zánětlivých autoimunitních onemocnění
- Očkování proti virové hemoragické horečce Ebola experimentální vakcínou rVSVDG-ZEBOV-GP
- Koronavirus hýbe světem: Víte jak se chránit a jak postupovat v případě podezření?
Najčítanejšie v tomto čísle
- Human Cytomegalovirus miR-UL112-3p Targets TLR2 and Modulates the TLR2/IRAK1/NFκB Signaling Pathway
- Paradoxical Immune Responses in Non-HIV Cryptococcal Meningitis
- Survives with a Minimal Peptidoglycan Synthesis Machine but Sacrifices Virulence and Antibiotic Resistance
- Fob1 and Fob2 Proteins Are Virulence Determinants of via Facilitating Iron Uptake from Ferrioxamine